Severance of polycarbonates and polycarbonate laminates with linear shaped charge

ABSTRACT

A method for severance of materials made of polycarbonate, polycarbonate laminate and acrylic/polycarbonate laminate utilizes a linear shaped explosive charge placed at a predetermined distance or stand off from the polycarbonate material to be severed. The coreload of the charge is determined such that the minimum coreload necessary to effect severance of a given thickness of polycarbonate material is utilized. A retainer is placed around the charge and affixed to the material such that the charge is at the proper stand off from the material. The retainer surrounds the back side of the charges but leaves open space between the charge and the material to be severed. Upon detonation, the charge creates an explosive cutting force, or jet blast, that severs the polycarbonate material. 
     Also, provided are methods for intersecting explosive charges about a pattern to be severed and methods for transferring detonation between such intersecting explosive charges.

FIELD OF THE INVENTION

The present invention relates to severing materials, such as an aircraft canopy made from polycarbonate, polycarbonate laminate or acrylic/polycarbonate laminate, with an explosive charge.

BACKGROUND

Most military aircraft contain an ejection seat that allows the pilot to escape the aircraft while in flight. When an ejection seat is jettisoned from the cockpit of an aircraft, it must pass through the region occupied by the transparent canopy of the aircraft. In instances where the canopy is not jettisoned prior to the ejection seat firing, the ejection seat must be capable of blasting entirely through the canopy. To reduce the risks to the pilot or other aircraft occupant attendant to forcing the ejection seat through the canopy, canopy fracture systems have been provided to fracture the canopy and better clear a path for the ejecting occupant so as to minimize bodily impact with the canopy.

Canopy fracture systems have been effective at removing portions of canopies that are made from fragilizing materials, such as cast or stretched acrylic. Fragilizing materials are those that may be caused to shatter into a significant number of pieces on application of sufficient pressure or explosive force. These systems utilize a mild detonating charge (MDC) or linear shaped charge (LSC) placed on, in or near the transparency which, upon detonation, creates shock waves that fracture the canopy. With fragilizing canopies, such as those made from cast or even stretched acrylic, it is not necessary to fully sever the material in order to defeat its structural integrity.

Many high performance aircraft utilize polycarbonate in their canopies instead of acrylic. Polycarbonate is a nonfragilizing material, meaning that it does not shatter on application of explosive force. With polycarbonate, it is absolutely necessary to fully sever the material because fracturing to complete the break is very unreliable. Because polycarbonate has a relatively low melt point and because cutting the material generates considerable heat there also exists a potential for resealing behind the cut if the severance is not complete.

U.S. Pat. No. 5,170,004 teaches an explosive device wherein a nearly incompressible transmitting medium is placed between the explosive device and an aircraft canopy. The function of the transmitting medium is to transmit the shock wave, produced upon detonation, to the canopy with a minimum of dissipation. This device is effective on fragilizing canopies but has not been successful with thicker non-fragilizing canopies made from monolithic polycarbonate, polycarbonate laminates or acrylic/polycarbonate laminates.

U.S. Pat. No. 5,780,763 teaches a method of fracture wherein explosive cords are placed in parallel grooves on the upper surface of a canopy and simultaneously detonated to create overlapping shock waves. This method is apparently capable of breaking a 0.75 inch thick polycarbonate in the laboratory at ambient temperature or below, but is unreliable at elevated temperatures on the order of 165° Fahrenheit or above. This method, however, requires two charges, grooves to be cut in the material and also utilizes shock waves which are not reliable on polycarbonate materials.

U.S. Pat. No. 5,954,296 also relates to an aircraft canopy fracture system. The 296 patent claims a canopy with a severable region shaped so as to inhibit passage of the severable region back through the canopy after severance. The 296 patent also refers to the use of a LSC to sever a polycarbonate canopy.

All documents, including other patents and references, referred to in this document are hereby incorporated by reference in their entirety, although no documents are admitted to render any of the claims unpatentable either alone or in combination with any other references known by the applicant.

The prior art also does not adequately deal with the problems of providing for severance around the comers of the severable portion of the target or for routing a charge over the top of another charge.

It is therefore an object of this invention to provide a severance method which severs materials such as polycarbonate, polycarbonate laminates or acrylic/polycarbonate laminates that cannot be severed by existing methods except by use of excessive amounts of explosive charge or by placing the charge inside the material to be fractured, thereby degrading the material's structural integrity.

It is another object of this invention to provide a severance method that allows for a minimum amount of explosive charge to sever a given thickness of material at high and low temperature extremes.

It is further an object of this invention to provide a severance method that allows for severance around comers and through intersecting portions of the explosive charge.

SUMMARY OF THE INVENTION

The present invention is a method for severing a non-fragilizing material such as polycarbonate with a linear shaped charge (“LSC”). Previous methods of polycarbonate, polycarbonate laminate or acrylic/polycarbonate laminate severance were either ineffective, or required imbedding explosive charges into the canopy itself. The prior art relies on the use of shock waves to fracture aircraft canopies. These methods, however, are not effective or reliable on canopies made from non-fragilizing materials such as polycarbonate, polycarbonate laminate or acrylic/polycarbonate laminate. The present invention discloses a method of using the cutting face of the explosive charges to sever a material such as polycarbonate, instead of relying on unreliable shock waves. Because the severance method of this invention is more effective and more reliable than previous severance methods, a lesser amount of explosive charge is required to effect target severance. In the case of a polycarbonate aircraft canopy target, the present invention's severance method provides pilots with a lower exposure to explosion back blast and noise.

An LSC is placed in proximity to the material to be severed at a distance sufficient to generate an explosive cutting face or “jet” adequate for cutting the target thickness. The LSC is held in place and at the sufficient distance by a retainer that surrounds the back of the charge. The retainer is adhered or attached to the target, again maintaining the appropriate distance between the charge and the target. Upon detonation, the charge severs the target. The charge and retainer may be tooled to provide for effective severance with minimum explosive force around corners. The present invention also provides for various methods of charge intersection, crossover and detonation transfer.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a side view of an explosive charge of the present invention attached to a target that is to be severed.

FIG. 2 is a side view of an explosive charge of the present invention after detonation severing the target material.

FIGS. 3a-d are tables showing performance test results of varying grain sizes of various LSCs on polycarbonates of varying thickness.

FIG. 4 is a depiction of a polycarbonate laminate and its target thickness.

FIG. 5 is a depiction of a severance pattern disclosed in U.S. Pat. No. 5,954,296.

FIG. 6 is a depiction of the crossover method of laying one LSC over another.

FIG. 6a is a depiction of a side view of the crossover method.

FIG. 6b is a depiction of a side view of the crossover method where a portion of the sheathing on the lower length of LSC has been cut away.

FIG. 6c is a depiction of a side view of the crossover method where a solid anvil is placed under the lower length of LSC to aid in detonation transfer.

FIG. 7 is a depiction of the invention's method of piggy-backing where one LSC comes up over a lower piece of LSC and rides the same line of severance for a given distance.

FIG. 7a is a side view of the piggyback method.

FIG. 8 is a depiction of the mitered joint method with four intersecting pieces of LSC.

FIG. 8a is a side view of the miter method.

FIG. 9 is a depiction of the miter method joining two lengths of LSC at a right angle.

FIG. 9a is a side view of the miter method used at a right angle.

FIG. 10 is a depiction of transferring LSC detonation through a crossover or intersection in the LSC utilizing a booster charge.

FIG. 10a is a depiction of transferring LSC detonation through a crossover or intersection in the LSC utilizing an explosive transfer charge encased in a manifold.

FIG. 11 is a depiction of transferring LSC detonation through a crossover or intersection in the LSC utilizing an explosive transfer charge encased in a manifold.

DETAILED DESCRIPTION

Referring to the drawings by reference numbers, FIG. 1 shows a linear shaped charge (“LSC”) 10 of the present invention in position on the target. The LSC is of a strength sufficient to sever a target, such as an aircraft canopy transparency, made from polycarbonate, polycarbonate laminate or acrylic/polycarbonate laminate.

The LSC 10 includes an explosive core 11 and a sheath 12. The best results are obtained when the LSC is shaped like a chevron with the opening facing and parallel to the target 13. There is open space between the LSC and the target. The LSC is surrounded by a retainer 14 that is attached to the target by some form of adhesive. The retainer attaches the LSC to the target such that the LSC is offset from the target by a distance 15 that allows the LSC to generate an explosive blast of sufficient strength to sever the target. FIG. 2 shows the present invention at the moment of explosion severing a target.

In a preferred embodiment the retainer is made from rubber and attached to the canopy with an epoxy or other adhesive. The retainer not only serves to hold the LSC in place at an appropriate distance from the canopy, it also acts to attenuate the back blast and noise from the explosion to protect the aircrew (in the case of a canopy target). The retainer may also be made from other type rubber products, an epoxy composite or other compounds and still achieve satisfactory results.

LSC sheathing is made of metal, typically tin, lead, aluminum, silver or copper. For severance of polycarbonates, tin, lead, and silver are preferable, but silver is rarely used due to high material costs. Testing was performed using PBXN-5/Lead, PBXN-5/Tin, HNS/Lead and HNS/Tin LSC of varying coreloads. Some of those test results are set forth in FIGS. 3a-3d. This testing revealed that a lead sheath is slightly more effective for severing polycarbonates than a tin sheath. Both are effective, however, and because of the hazards of working with lead, a tin sheath is the preferred embodiment. A tin sheath is slightly more effective than a lead sheath in severing aluminum. Testing also determined that PBXN-5 powder is superior to HNS powder.

Because of the lack of success with previous canopy fracturing and severance methods in polycarbonate canopies, a great deal of testing was performed to determine the proper LSC coreload and stand off necessary to sever a set thickness of polycarbonate. In the present invention the coreload and stand-off necessary to sever polycarbonates of varying thickness is disclosed. As would be expected, the thicker the polycarbonate to be severed, the greater the coreload required. The LSC is more effective if setoff a certain distance from the target. A tabular representation of the test results achieved on varying polycarbonate thicknesses with varying LSC coreload, powder sheathing, back ups and stand-off is set forth below:

IDENTIFICATION Back TEST # SOURCE INFORMATION NOTES Up Thickness Penetration 1 UDRI Dow-Calibre 300-6, ¾″, #4 12 gr/ft HNS/Lead, RTV, No Stand-Off(SO), retainer 0.75 .045/broke Parallel Beam, Broke 2 UDRI Dow-Calibre 300-6, ¾″, #2 20 gr/ft RDX/Lead, RTV, No SO, Parrallel Beam, Broke retainer 0.75 broke 3 UDRI Dow-Calibre 300-6, ¾″, #9 12 gr/ft HNS/Lead, RTV, No SO, Bottom Clamped, retainer 0.75 0.05 .05 Imp., B-U 4 UDRI Dow-Calibre 300-6, ¾″, #12 21 gr/ft CH6/Al, 0.090 SO, 0.275 Penetration, TMD 0.75 .15/break Cracked Through 5 UDRI Dow-Calibre 300-6, ¾″, #14 21 gr/ft CH6/Al, No SO, 0.180 Penetration, TMD 0.75 .180(break Some cracking 6 UDRI Dow-Calibre 300-6, ¾″, #15 21 gr/ft CH6/Al, No SO, RTV filled, Little Penetration TMD 0.75 0.075 8 UDRI Dow-Calibre 300-6, ¾″, #3 40 gr/ft PBXN5/Lead, .180 SO, inside radius-straight, cut rubber 0.075 broke 33 Texstar Coated In C678, Out C992, {fraction (5/16)}″ 12 gr/ft, HNS/Tin, 0.125 SO, some pen, all melted, rubber 0.312 0.19 no cut 34 Texstar Coated In C678, Out C992, {fraction (5/16)}″ 12 gr/ft, PBXN-5/Tin, 0.160 SO, Cut rubber 0.312 cut 35 Texstar Coated In C678, Out C992, {fraction (5/16)}″ 12 gr/ft, PBXN-5/Tin, .160 SO, 90° Angle, paper 0.312 0.3 Cut except angle 36 Texstar Coated In C678, Out C992, {fraction (5/16)}″ 12 gr/ft, PBXN-5/Tin, .160 SO, unrestrained, Cut paper 0.312 cut 37 Texstar Coated In C678, Out C992, {fraction (5/16)}″ 12 gr/ft, HNS/Tin, 0.125 SO, Unrestrained, Cut paper 0.312 cut 38 Texstar Coated In C678, Out C992, {fraction (5/16)}″ 15 gr/ft, HNS/Tin, 0.125 SO, cut rubber 0.312 cut 39 Texstar Coated In C678, Out C992, {fraction (5/16)}″ 12 gr/ft, PBXN5/Tin, 360° sep test, cut & broke rubber 0.323 cut 49 Texstar Coated In C678, Out C992, ⅜″ 12 gr/ft, PBXN-5/Tin, 0.160 SO, Nearly Severed paper 0.375 0.18 50 Texstar Coated In C678, Out C992, ⅜″ 12 gr/ft, HNS/Tin, 0.125 SO, cut rubber 0.375 cut 51 Texstar Coated In C678, Out C992, ⅜″ 15 gr/ft, HNS/Tin, 0.125 SO, cut rubber 0.375 cut 52 Texstar Coated In C678, Out C992, ⅜″ 12 gr/ft, PBXN5/Tin, 0.130 SO, remelted + D73 rubber 0.375 cut 53 Texstar Coated In C678, Out C992, ⅜″ 12 gr/ft, HNS/Lead, 0.130 SO, remelted rubber 0.375 cut 15 gr/ft, PBXN5/Tin, .15 SO, 360° 2″ R Bend - sep. test, cut except 54 Texstar Coated In C678, Out C992, ⅜″ joint rubber 0.375 not joint 65 Texstar Coated In C678, Out C992, ½″ 15 gr/ft, PBXN-5/Tin, 0.160 SO, some paper 0.5 0.35 penetration, mostly melted 66 Texstar Coated In C678, Out C992, ½″ 15 gr/ft, PBXN-5/Lead, 0.160 SO, paper 0.5 0.4 melted but not severed 67 Texstar Coated In C678, Out C992, ½″ 15 gr/ft, PBXN-5/Lead, 0.160 SO, unrestrained, paper 0.5 0.41 some pen, melted 68 Texstar Coated In C678, Out C992, ½″ 15 gr/ft, PBXN-5/Tin, 0.160 SO, unrestrained paper 0.5 0.445 69 Texstar Coated In C678, Out C992, ½″ 15 gr/ft, PBXN5/Lead, 90 deg bend, 0.150 SO, close paper 0.5 cut/not bend 70 Texstar Coated In C678, Out C992, ½″ 15 gr/ft, PBXN5/Tin, 90 deg bend, 0.150 SO, paper 0.5 cut/.36 shattering, close 71 Texstar Coated In C678, Out C992, ½″ 15 gr/ft, PBXNS/Lead, 200 deg F., 0.150 SO, remelted rubber 0.5 cut/remelted 72 Texstar Coated In C678, Out C992, ½″ 15 gr/ft, PBXNS/Tin, 200 deg F., 0.150 SO, paper? 0.5 cut unteth, hanging thread 73 Texstar Coated In C678, Out C992, ½″ 15 gr/ft, PBXN5/Lead, −65° F., 0.150 SO, cut rubber 0.5 cut 74 Texstar Coated In C678, Out C992, ½″ 15 gr/ft, PBXN5/Tin, −65° F., 0.150 SO, cut rubber 0.5 cut 75 Texstar Coated In C678, Out C992, ½″ 20 gr/ft, PBXN-5/Lead, unteth, cut rubber 0.5 cut 76 Texstar Coated In C678, Out C992, ½″ 20 gr/ft, PBXN-5/Tin, unteth, cut rubber 0.5 cut 77 Texstar Coated In C678, Out C992, ½″ 20 gr/ft, PBXN-5/Tin, unteth, some penetration, rubber 0.5 cut/.45 S curve, not cut 78 20 gr/ft, PBXN-5/Lead, .145 SO, “S” turn, not cut rubber 0.55 cut/.45 in bends 79 Texstar Coated In C678, Out C992, ½″ 15 gr/ft, PBXN-5/Tin, 90° turn, 0.145 SO, rubber 0.5 0.32 restrained, 2″ radius 80 Texstar Coated In C678, Out C992, ½″ 15 gr/ft, PBXN-5/Lead, 90° turn, 0.145 SO, rubber 0.5 cut/99% restrained, 2″ radius 81 Texstar Coated In C678, Out C992, ¾″ 30 gr/ft, PBXN-5/Lead, unrestrained, .175 SO,cut paper 0.75 cut 82 Texstar Coated In C678, Out C992, ¾″ 30 gr/ft, PBXN-5/Tin, unrestrained, .175 SO, paper 0.75 0.54 .540 pen, cracked 83 Texstar Coated In C678, Out C992, ¾″ 30 gr/ft, HNS/Lead, 0.150 SO, .480 pen, some cracking paper 0.75 0.48 84 Texstar Coated In C678, Out C992, ¾″ 30 gr/ft, HNS/Tin, 0.120 SO, unteth, .440 pen rubber 0.75 0.44 85 Texstar Coated In C678, Out C992, ¾″ 30 gr/ft, PBXN5/Lead, 0.150 SO, −70° F., Cut rubber 0.75 cut 86 Texstar Coated In C678, Out C992, ¾″ 30 gr/ft, PBXN5/Lead, 0.150 SO, 200° F., rubber 0.75 cut untethered, cut 87 Texstar Coated In C678, Out C992, ¾″ 30 gr/ft, PBXN5/Lead, 0.182 SO, 200° F., rubber 0.75 cut restrained, cut 88 Texstar Coated In C678, Out C992, ¾″ 30 gr/ft, PBXN5/Lead, 0.182 SO, 200° F., rubber 0.75 cut unrestrined, cut 105 NSWC MX2054-920415, 0.500 .530 thick, 15 gr/ft PBXN5/Lead, .150 SO, rubber 0.53 0.5 Nearly severed 106 NSWC MX2054-920415, 0.500 .530 thick, 20 gr/ft PBXN5/Lead, .150 SO, 90° bend, cut rubber 0.53 cut 109 Pilkington 0.250 × 36 × 60 12 gr/ft, 815525-2 (Min/Max), RTV, No SO, no SO 0.25 0.12 No Cut, cracked thru 110 Pilkington 0.250 × 36 × 60 12 gr/ft, 815525-2 (Min/Max), RTV, No SO, no SO 0.25 cut/melted Scored, cut & melted 111 Pilkington 0.250 × 36 × 60 12 gr/ft, 815525-2 (Min/Max), No SO, No cut no SO 0.25 .05/cracking 112 Pilkington 0.250 × 36 × 60 12 gr/ft, 815525-2 (Min/Max), No SO, No cut no SO 0.25 .04/melting 113 Pilkington 0.250 × 36 × 60 12 gr/ft, 815525-2 (Min/Max), 0.110 SO, rubber 0.25 cut Use CH 825252, Cut 114 Pilkington 0.250 × 36 × 60 12 gr/ft, 815525-2 (Min/Max), 0.110 SO, rubber 0.25 cut Use CH 825252, Cut 116 Pilkington 0.250 × 36 × 60 12 gr/ft, HNS/Tin, 0.110 SO, Use CH 825252(?), Cut paper 0.25 cut 118 Pilkington 0.250 × 36 × 60 12 gr/ft, PBXN-5/Tin, 0.110 SO, Use CH 825252(?), Cut paper 0.25 cut 119 Pilkington 0.250 × 36 × 60 12 gr/ft, HNS/Lead, 0.110 SO, 200° F., Cut rubber 0.25 cut 120 Pilkington 0.250 × 36 × 60 12 gr/ft, HNS/Lead, 0.110 SO, RTV Filled, rubber 0.25 0.025 Poor Performance 125 Pilkington 0.312 × 36 × 60 12 gr/ft, HNS/Lead, 0.110 SO, No Cut rubber 0.312 .28/pen 126 Pilkington 0.312 × 36 × 60 12 gr/ft, HNS/Lead, 0.145 SO, No Cut rubber 0.312 0.22 127 Pilkington 0.312 × 36 × 60 15 gr/ft, HNS/Lead, 0.145 S.O., Cut rubber 0.312 cut 128 Pilkington 0.312 × 36 × 60 15 gr/ft, PBXN-5/Lead, 0.145 S.O., Cut rubber 0.312 cut 129 Pilkington 0.312 × 36 × 60 12 gr/ft, PBXN-5/Tin, 0.1 10 SO, Use CH 825252, paper 0.312 cut Cut but Remelted 141 Pilkington 0.350 × 36 × 60 15 gr/ft, HNS/Lead, 0.145 S.O., Cut rubber 0.35 cut 142 Pilkington 0.350 × 36 × 60 15 gr/ft, PBXN-5/Lead, 0.145 S.O., Cut rubber 0.35 cut 143 Pilkington 0.350 × 36 × 60 15 gr/ft, PBXN-5/Tin, 0.145 S.O., Cut paper 0.35 cut 167 Texstars 0.310 Ply Laminate 12 gr/ft PBXNS/Tin, .15 SO, Gap Test, rubber 0.312 cut/not jnt Gap did not break 173 Sierracin 0.375 Ply Laminate 15 gr/ft HNS/Lead, 0.145 SO, Cut rubber 0.375 cut 174 Sierracin 0.375 Ply Laminate 15 gr/ft PBXN-5/Lead, 0.145 SO, Cut rubber 0.375 cut 175 Sierracin 0.375 Ply Laminate 15 gr/ft PBXN-5/Tin, 0.145 SO, Cut paper 0.375 cut 176 Texstars 0.375 Ply Laminate 12 gr/ft PBXN5/Tin, .070 SO, Untethered, butted joint, rubber 0.375 cut/not jnt cut, not joint 177 Sierracin 0.375 Ply Laminate 12 gr/ft, PBXN-5/Tin, 0.070 SO, Cut joint rubber 0.375 cut joint 178 Sierracin 0.375 Ply Laminate 12 gr/ft, PBXN-5/Tin, 0.150 SO, cut 1 end, rubber 0.375 0.305 .235 pen other end 181 Sierracin 0.500 Ply Laminate 15 gr/ft HNS/Lead, 0.145 SO, No Cut, .310 Penetration rubber 0.5 0.31 182 Sierracin 0.500 Ply Laminate 15 gr/ft PBXN-5/Lead, 0.145 SO, Cut rubber 0.5 cut 183 Sierracin 0.500 Ply Laminate 20 gr/ft HNS/Lead, 0.145 SO, No Cut, .450 Penetration rubber 0.5 0.45 184 Sierracin 0.500 Ply Laminate 20 gr/ft PBXN-5/Lead, 0.145 SO, Cut rubber 0.5 cut 185 Sierracin 0.500 Ply Laminate 15 gr/ft PBXN-5/Lead, 0.145 SO, Cut but remelted rubber 0.5 cut 186 Sierracin 0.500 Ply Laminate 15 gr/ftPBXN-5/Lead, 0.145 SO, 200° F., Cut rubber 0.5 cut 187 Sierracin 0.500 Ply Laminate 15 gr/ftPBXN-5/Lead, 0.145 SO, −65° F., Cut rubber 0.5 cut 188 Sierracin 0.500 Ply Laminate 15 gr/ft PBXN-5/Lead, 0.145 SO, Cut but remelted paper 0.5 cut 189 Sierracin 0.750 Ply Laminate 25 gr/ft HNS/Lead, 0.145 SO, No Cut, ˜0.420 rubber 0.75 0.42 Penetration 190 Sierracin 0.750 Ply Laminate 30 gr/ft HNS/Lead, 0.145 SO, No Cut, ˜0.450 paper 0.75 0.45 Penetration 191 Sierracin 0.750 Ply Laminate 20 gr/ft PBXN-5/Lead, 0.145 SO, No Cut, ˜0.450 rubber 0.75 0.4 Penetration 192 Sierracin 0.750 Ply Laminate 25 gr/ft PBXN-5/Lead, 0.145 SO, No Cut, ˜0.550 rubber 0.75 0.55 Penetration 193 Sierracin 0.750 Ply Laminate 30 gr/ft PBXN-5/Lead, 0.165 SO, Cut paper 0.75 cut 194 Sierracin 0.750 Ply Laminate 30 gr/ft PBXN-5/Tin, 0.145 SO, No Cut, ˜0.550 paper 0.75 0.55 Penetration 195 Sierracin 0.750 Ply Laminate 15 gr/ft PBXN-5/Lead, 0.145 SO, ˜0.440 paper 0.75 0.44 Penetration 196 Sierracin 0.750 Ply Laminate 30 gr/ft PBXN-5/Lead, 0.165 SO, Cut Partially paper 0.75 0.7 197 NSWC-IH 0.500 D910108-06 15 gr/ft PBXN-5/Lead, 0.145 SO, 90 deg, 1 of 90's none 0.5 0.46 not cut 198 NSWC-IH 0.500 D910108-06 15 gr/ft PBXN-5/Lead, 0.145 SO, 90 deg, some pen. none 0.5 0.4 not cut 199 NSWC-IH 0.500 15 gr/ft, PBXN-5/Tin, 0.145 SO, some pen, all melted, paper 0.5 0.42 no cut 200 NSWC-IH 0.500, 15 gr/ft, PBXN-5/Lead, 0.145 SO, remelted 0.5 .46/cut 205 Sierracin 0.750 30 gr/ft, PBXN-5/Tin, 0.275 SO, ˜.550 Pen., paper 0.75 0.55 Crack & Melt, No Cut 206 Sierracin 0.750 30 gr/ft, PBXN-5/Lead, 0.250 SO, ˜.650 to Cut, paper 0.75 .675/cut No Sep, remelted 207 WPAFB 0.750 40 gr/ft, HNS/Lead, 0.150 SO, cut, unrestrained rubber 0.75 cut 208 WPAFB 0.750 40 gr/ft, HNS/Tin, 0.190 SO, .480 pen, unrestrained rubber 0.75 0.48 209 WPAFB 0.750 40 gr/ft, PBXN5/Lead, 0.200 SO, cut, unrestrained rubber 0.75 cut 210 WPAFB 0.750 40 gr/ft, PBXN5/Tin, 0.230 SO, cut, unrestrained rubber 0.75 cut 213 Texstar Coated In C678, Out C992, ½″ 15 gr/ft, PBXN5/Lead, 90 deg bend, 0.150 SO, paper/- 0.53 .48/cut cut/0.48 penetration 214 Texstars Coated In C678, Out C992, ½″ 25 gr/ft, HNS/Tin, 0.150 SO, restrained, −65° F., cut rubber 0.54 cut 215 Texstars Coated In C678, Out C992, ½″ 25 gr/ft, HNS/Tin, 0.150 SO, Broke, 0.475 Pen rubber 0.54 0.475 216 Texstars Coated In C678, Out C992, ½″ 15 gr/ft, PBXN5/Lead, 0.150 SO, 200° F., rubber 0.54 cut Unrestrined, Cut 217 Texstars Coated In C678, Out C992, ½″ 15 gr/ft, PBXN5/Lead, 0.15O SO, restrained, cut rubber 0.54 0.5 218 Navy ½″, MX2054-920415 20 gr/ft PBXN5/Tin, 0.185 SO, 90° bend, rubber 0.5 cut 2″ R, untethered, cut 220 Texstars ½″, Coated In C678, Out C992 17.5 gr/ft PBXN5/Tin, 185 SO, 90° bend, 2″ R, not cut rubber 0.53 0.22 221 Texstars 0.740 Laminated, special 40 gr/ft PBXN5/Lead, 0.200 SO, Cut rubber 0.74 cut 222 Sierracin 0.500 Inch 20 gr/ft PBXN5/Lead, 0.15 SO, 90° bend, 2″ R, rubber 0.5 cut 200° F., cut 223 Sierracin 0.500 Inch 20 gr/ft PBXN5/Lead, 0.15 SO, 90° bend, 2″ R, −65° F. rubber 0.5 cut 224 Sierracin 0.500 Inch 15 gr/ft PBXN5/Lead, 0.15 SO, untethered, cut rubber 0.5 cut 225 Sierracin 0.500 Inch 15 gr/ft PBXN5/Lead, 0.15 SO, tethered, cut rubber 0.75 cut 226 Sierracin 0.75 inch 30 gr/ft PBXN5/Lead, 0.15 SO, cut rubber 0.75 cut 15 gr/ft PBXN5/Lead, 0.15 SO, 1/2″ RTV filled Apex, not cut in RTV 228 Texstars 0.50 inch area rubber 0.5 not RTV 231 UDRI 0.75 inch 12 gr/ft PBXN5/Tin, 0.100 SO, .285 pen rubber 0.765 0.285 232 UDRI 0.75 inch 15 gr/ft PBXN5/Tin, 0.100 SO, .36 pen rubber 0.765 0.36 233 UDRI 0.75 inch 15 gr/ft PBXN5/Lead, 0.100 SO, .33 pen rubber 0.765 0.33 17.5 gr/ft PBXN5/Tin, .100 SO, HMR-T98-1321, .320 pen, cracking 234 UDRI 0.75 inch thru rubber 0.765 0.32 235 UDRI 0.75 inch 17.5 gr/ft PBXN5/Tin, .100 SO, LMR-T98-1323, .32 pen rubber 0.765 0.32 236 UDRI 0.75 inch 17.5 gr/ft PBXN5/Lead, .110 SO, HMR-T98-1322, rubber 0.765 0.3 .30 pen 237 UDRI 0.75 inch 17.5 gr/ft PBXN5/Lead, .110 SO, LMR-T98-1320, rubber 0.765 0.31 .31 pen 238 UDRI 0.75 inch 20 gr/ft PBXN5/Tin, 0.150 SO, .57 pen rubber 0.765 0.57 239 UDRI 0.75 inch 20 gr/ft PBXN5/Lead, 0.110 SO, .4 pen rubber 0.765 0.4 240 UDRI 0.75 inch 22.5 gr/ft PBXN5/Tin, .110 SO, HMR-T98-1321, rubber 0.765 0.48 .48 pen 22.5 gr/ft PBXN5/Tin, .110 SO, LMR-T98-1323, .45 pen, 99% 241 UDRI 0.75 inch broken rubber 0.765 0.45 242 UDRI 0.75 inch 22.5 gr/ft PBXN5/Lead, .150 SO, HMR-T98-1322, rubber 0.765 0.58 .58 pen 243 UDRI 0.75 inch 22.5 gr/ft PBXN5/Lead, .100 SO, LMR-T98-1320, rubber 0.765 0.37 .37 pen 244 UDRI 0.75 inch 25 gr/ft PBXN-5/Tin, 0.190 SO, .6 pen, cut rubber 0.765 cut 245 UDRI 0.75 inch 25 gr/ft PBXN-5/Lead, 0.190 SO, .6 pen rubber 0.765 0.6 246 UDRI 0.75 inch 30 gr/ft PBXN5/Tin, 0.190 SO, .60 pen, cut rubber 0.765 cut 247 UDRI 0.75 inch 30 gr/ft PBXN5/Lead, 0.150 SO, 0.69 pen rubber 0.765 0.69 248 UDRI 0.75 inch 40 gr/ft PBXN5/Tin, 0.200 SO, cut rubber 0.765 cut 249 UDRI 0.75 inch 40 gr/ft PBXN5/Lead, 0.200 SO, Cut rubber 0.765 cut 250 Navy D910108-08 20 gr/ft PBXN5/Lead, 0.150 SO, 1/2″ RTV Block, rubber 0.53 0.5 no cut under RTV 251 Texstars 0.375 inch 15 gr/ft PBXN5/Tin, 0.15 SO, 360° turn butt rubber 0.375 not at joint up with angle cut 252 Texstars 0.375 inch 15 gr/ft PBXN5/Tin, 0.15 SO, 360° turn with overlap rubber 0.375 cut 253 0.75 inch 25 gr/ft PBXNS/Tin, 0.190 SO, partial cut then broke rubber 0.75 cut 254 0.75 inch 30 gr/ft PBXN5/Tin, 0.190 SO, bent 120° but hanging. rubber 0.75 cut- 40 gr/ft PBXN5/Tin, 0.200 SO, 360° turn with overlap, broke, but not 255 0.75 inch a nice clean cut rubber 0.75 cut 15 gr/ft PBXN5/Tin, .150 SO, 360° turn with overlap, 0.40 pen, cut 256 Navy D910108-08 overlap Isc off rubber 0.53 0.4 20 gr/ft PBXN5/Lead, .180 SO, 360° turn with overlap, some pen. 257 Navy D910108-08 But most 0.40 + rubber 0.53 0.4 25 gr/ft PBXN5/Lead, .180 SO, 360° turn with overlap, mostly cut 258 Navy D910108-08 except overlap rubber 0.53 cut 15 gr/ft PBXN5/Tin, .150 SO, 360° turn with overlap, broke but only 259 Navy D910108-08 0.37 pen. rubber 0.53 0.37 15 gr/ft PBXN5/Tin, .150 SO, 360° turn with piggyback overlap, .36 260 Navy D910108-08 pen. rubber 0.53 0.36 20 gr/ft PBXN5/Lead, .15O SO, 360° turn with piggyback overlap., 261 Navy D910108-08 did not cut overlap rubber 0.53 cut/not over 25 gr/ft PBXN5/Lead, .150 SO, 360° turn with piggyback overlap, 262 Navy D910108-08 did not cut overlap rubber 0.53 cut/not over 263 Navy D91 01 08-08 20 gr/ft PBXN5/Tin, Cross over, .150 SO, rubber 0.53 cut/not over cut bottom LSC without detonating 264 .500 inch 15 gr/ft PBXN5/Tin, loop with mitered joint, .150 SO, rubber 0.5 0.3 did not cut 265 .500 inch 15 gr/ft PBXN5/Tin, loop with mitered joint, .150 SO, rubber 0.5 0.3 did not cut 266 .500 inch 25 gr/ft PBXN5/Tin, “D” shape with mitered corners, rubber 0.5 cut .150 SO, Cut nicely 270 Sierracin 1.00 inch, 7 ply laminate 40 gr/ft PBXN5/Tin, 90° mitered angle, .180 SO, cut rubber 1 cut nicely 271 Texstars .375 Coated 12 gr/ft PBXN5/Tin, 0.070 SO, .300 pen rubber 0.375 0.3 272 Sierracin .500 Laminated 12 gr/ft PBXN5/Tin, .070 SO, cut rubber 0.5 cut 273 Sierracin .500 Laminated 15 gr/ft PBXN5/Tin, .070 SO, .360 pen rubber 0.5 0.36 274 Navy .500 cast 25 gr/ft PBXN5/Tin, . 150 SO, “O” with T Mitered, Cut rubber 0.5 cut 278 Sierracin Laminated .448 12 gr/ft PBXN5/Tin, .070 SO, 90° bend, cut rubber 0.448 cut 279 Sierracin .448 Laminated 12 gr/ft PBXN5/Tin, .070 SO, 90° bend, cut rubber 0.448 cut 280 Sierracin .525 Laminated 15 gr/ft PBXN5/Tin, .150 SO, 90° bend, nearly rubber 0.525 99% cut completely severed 281 Sierracin .525 Laminated 12 gr/ft PBXN5/Tin, .150 SO, 200° F., 90° bend, rubber 0.525 0.36 did not cut 282 Sierracin .525 Laminated 15 gr/ft PBXN5/Tin, .150 SO, 200° F., 90° bend, cut rubber 0.525 cut 283 Sierracin .448 Laminated 12 gr/ft PBXN5/Tin, .070 SO, 200° F., 90° bend, cut rubber 0.448 cut

Previous methods of aircraft canopy fracturing and severance relied on the use of shock waves generated from an explosive charge. In order to facilitate shock wave transfer from the explosive charge to the target, U.S. Pat. No. 5,170,004 taught the use of a nearly incompressible medium placed between the charge and target. While this method is effective on acrylic and other fragilizing type materials it is not reliable with polycarbonate, polycarbonate laminate or acrylic/polycarbonate laminates. With polycarbonate type materials, the use of an incompressible or other medium between the LSC and the target degrades rather than improves results. This is because polycarbonates are not easily fractured and therefore cutting using the explosive “jet” blast of the LSC is preferable to fracturing using shock waves. Because severance is preferable to fracturing, it is important that the area between the LSC and the target be clear of debris. This goes against the teaching of the 004 patent which taught the use of some form of nearly incompressible medium between the charge and the target in order to facilitate transmission of shock waves.

U.S. Pat. No. 5,780,763 taught a method of fracture wherein explosive charges are placed in parallel grooves cut in the upper surface of the material and simultaneously detonated to create overlapping shock waves. Again, because this method relies on shock waves which are unreliable to sever polycarbonate materials it is inferior to the present invention that uses the unimpeded explosive “jet” blast of the LSC to sever the material.

As revealed by the test results set forth above, the best severance results are obtained by use of a rubber back up, a PBXN-5 powder and a lead or tin sheath. Ideal set off was in the range of 0.100 to 0.300 inch for coreloads of 12 to 40 grains per foot.

Laminates of polycarbonate, acrylic, stretched acrylic and polyurethane can be severed with less overall energy than pure polycarbonate. The target thickness for the laminate is the total thickness from the LSC side through the final layer of polycarbonate or polyurethane. FIG. 4 shows the target thickness of a laminate. Any acrylic outside the final polycarbonate or polyurethane layer is easily shattered by the shock wave created by the LSC severing the polycarbonate. Acrylic layers between the LSC and the final layer or polycarbonate or polyurethane will act very much like the polycarbonate for the entire thickness.

Another shortcoming in the prior art was difficulty in safely severing polycarbonates and other materials around comers. To create a passageway for an ejecting or egressing aircrew it is necessary that the LSC circumscribe some pattern sufficient to allow egress. Severance problems arise when the LSC is bent around the comers of this pattern. These problems are attributable to at least two factors. First, in bending the LSC the coreload may be disbursed to less than an optimum strength, especially on the outside of the bend. Second, when the LSC and its retainer are bent around corners, the open end of the chevron may be shifted from parallel to the target surface. Optimal results are achieved when the open end of the chevron is parallel to the target surface and the explosive force is therefore perpendicular to that surface. Any alteration from parallel lessens the explosive force striking the target and impedes severance.

Therefore, in a preferred embodiment of this invention, bends in the LSC are gentle, with turn radii kept on the order of 2 inches or above. In this way the coreload of the LSC is kept consistent. Additionally, both the LSC and its retainer are tooled so as to keep the open end of the LSC chevron parallel to, and the apex of the chevron and resulting explosive force perpendicular to, the target. Through these methods, the full force of the explosive charge is expended directly on and perpendicular to the target. This allows severance with a minimum of coreload, thereby reducing noise and back blast.

The LSC must be placed on the target in a pattern that will effect severance of a portion of the target. In the prior art the LSC was not able to crossover another length of LSC. Instead the LSC would be bent around as it approached another length of LSC. FIG. 5 is a depiction of a LSC pattern on the severable portion of an aircraft canopy, as disclosed in the 296 patent discussed above. In FIG. 5 it can be seen that the charges must turn at sharp bends where it would be simpler, require less LSC and tooling, and avoid the degradation in performance associated with sharp bends if a length of LSC could simply intersect or crossover another length. This invention effects such intersections and crossovers in several ways.

FIG. 6 depicts one crossover method. A first length of LSC 20 is first run along the target. A second length of LSC 21, intersecting the first length, can then be run over the top of the first length. When a crossover method is utilized the second length of LSC must be detonated before the first. If the first length of LSC is detonated before the second length it will blow the second length off the target and greatly impede the severance capability of the LSC. Additionally, the crossover must be designed so that upon detonation, the second length of LSC detonates the first length of LSC. If the second length of LSC merely severs the first length, without detonating it, the severing capability of the LSC will be again greatly reduced.

FIG. 6a shows the second length of LSC 21 flattened over the first length of LSC 20. By flattening the second length of LSC 21 its cutting force is reduced and it will detonate, instead of sever, the first length of LSC 20. It may also be desirable to cut away some of the metal sheathing on the top of the first length of LSC 20 to assist detonation by reducing the amount of metal sheathing that the second length of LSC 21 must detonate through in order to detonate the first length of LSC 20. FIG. 6b shows the crossover method wherein the first length of LSC 20 has part of its metal sheathing cut away indicated by numeral 23 to facilitate its detonation by the second length of LSC 21. This may be especially important in higher coreload material.

Another method of ensuring detonation of the first length of LSC by the second length is to insert a solid material under the first length of LSC so that upon detonation of the second length of LSC the first length is forced against the solid material to assist in detonation transfer. FIG. 6c shows a solid anvil type object 22 placed under the first length of LSC 20. The anvil adds reliability to the detonation transfer, especially with higher coreload LSC severance.

A variation on the crossover method is shown in FIG. 7. In this method the second length of LSC 21 comes up on the first length of LSC 20 and rides the same line of severance for some given distance. This crossover method (referred to as a piggyback) not only avoids the sharp bend problem, it can also be used to add to the cutting capability of the first length of LSC and should be considered in areas of the target material that are thicker than other areas. In the piggyback method it is also important to fire the second length of LSC first. Firing the first length (the length closest to the target) first could result in blowing the second length off the target. FIG. 7a shows a side view of the piggy back method.

An additional method of routing LSC through intersections in a pattern is the mitered joint. FIG. 8 shows a four way mitered joint. The LSC is cut on the appropriate angle (i.e. 45°) to meet with another end of LSC that is similarly mitered. The joint is then joined with an adhesive. Appropriate adhesives include C-7/W and 5-minute epoxy. FIG. 8a depicts a crossview of the four way mitered joint. FIG. 9 shows a method of joining two lengths of LSC at a right angle. As with the crossover method, if one mitered joint is to ride over another it is important that the LSC closest to the target is not detonated until after the other length of LSC.

FIG. 10 shows another method of LSC intersection. In FIG. 10, a booster charge 30 is placed at the intersection of the adjoining lengths of LSC. The lengths of LSC abut to the booster charge that transfers detonation through the intersection. While booster charges have been used to transfer detonation in other mediums, they have not been utilized with LSC. FIG. 11 shows an LSC intersection where an explosive transfer charge powder 40, typically HNS or PBNX-5, is enclosed in a manifold 41 that assists in transferring detonation. These methods do not provide for cutting under the booster or transfer charge but can provide for breaking at that point. Additionally, the manifold method is limited in use because the manifold becomes a projectile upon detonation if not retained. Therefore, in the case of aircraft transparency severance, the manifold method is limited to use on the sill of the aircraft, where it can be retained by a retainer mounted over the LSC and held to the aircraft's fuselage.

The retainer is not shown in the intersection figures, but those skilled in the art will recognize that a charge holder can be designed to take account of the LSC intersection or crossover.

The severance method of the present invention may be utilized in a system designed so as to be seated proximal to a sill portion of the aircraft and the system may include, in addition to the above-described arrangement for freeing a severable region of the canopy, one or more explosive charge positioned on or in close proximity to at least a portion of the sill and that will, on detonation, free substantially the entire transparent portion of the canopy from the aircraft. The present system also may be designed so as to selectively initiate either the detonation of the explosive charges mounted on or near the sill so as to sever substantially the entire transparent portion of the canopy or the severance of the smaller, severable region of the canopy. Detonation of the explosive charges mounted on or near the sill may be preferred over severing the severable region of the canopy in situations where the aircraft is on the ground or is otherwise not in flight and immediate egress from the cockpit is necessary.

The present severance method may also be designed so that the one or more explosive charges mounted on or near the sill detonate and free a large portion of the canopy from the aircraft simultaneous with the fracturing of the smaller, severable region to allow egress from the aircraft. Alternately, the present severance method may be used in a system to provide for the detonation of the one or more explosive charges mounted on or near the sill after the fracturing and severance of the smaller, severable region.

Various other details of the design and implementation of aircraft canopy fracturing systems will be apparent to those of ordinary skill in the art and, therefore, are not provided herein. Such details are in part provided in, for example, “A Systems Engineering Design Guide to Aircraft Explosive Canopy Fracturing”, December 1993, Teledyne Ryan Aeronautical, McCormick Selph Ordinance, the entire content of which is incorporated herein by reference.

Those of ordinary skill in the art also will appreciate that various changes in the details and arrangements of parts and materials which have been herein described and illustrated in order to teach the nature of the invention may be made by those skilled in the art. Any such modifications remain within the principle and scope of the invention as expressed in its claims. 

What is claimed is:
 1. A method of severing a material, comprising the steps of: selecting a pattern to be severed on said material, said material including a polycarbonate or a laminate including polycarbonate, all bends in said pattern having turn radii of greater than or equal to 2 inches; surrounding a linear explosive charge in a retainer such that an area of said linear explosive charge is not surrounded by said retainer and said area of said linear explosive charge not surrounded by said retainer faces said material, said retainer being made of a rubber; attaching said retainer to said material along said pattern such that there is an open space between said linear explosive charge and said material; and detonating said linear explosive charge so that said material is severed along said pattern.
 2. A method of severing a material, comprising the steps of selecting a severance site on said material, said material, including a polycarbonate or a laminate including polycarbonate; surrounding a linear explosive charge in a retainer such that an area of said linear explosive charge is not surrounded by said retainer and said area of said linear explosive charge not surrounded by said retainer faces said material, said retainer being made of silicone rubber, said linear explosive charge including a coreload of 10 to 40 grains per foot; attaching said retainer to said material such that there is an open space to provide an offset in a range of 0.070 to 0.300 inches between said linear explosive charge and said material such that, upon detonation, said linear explosive charge generates an explosive cutting face to sever said material at said severance site, all bends in said linear explosive charge having turn radii of greater than or equal to 2 inches; and detonating said linear explosive charge.
 3. The method of claim 1, further comprised of said linear explosive charge being a linear shaped charge with a V shaped cross section.
 4. The method of claim 3, further comprised of said linear explosive charge comprising a metal sheathing of tin.
 5. The method of claim 3, further comprised of said linear explosive charge comprising a metal sheathing of lead.
 6. The method of claim 3, further comprised of said retainer and said linear explosive charge are tooled such that an open end of said V shaped cross section of said linear shaped charge is at all times aligned with said material.
 7. The method of claim 3, further comprised of said linear shaped charge with said V shaped cross section is placed to provide an offset in a range of 0.100 to 0.300 inches.
 8. The method of claim 7, further comprised of said linear shaped charge with said V shaped cross section including a coreload in a range of 12 to 40 grains per foot.
 9. The method of claim 7, further comprised of said polycarbonate or laminate including polycarbonate material being of a thickness on the order of 0.1 to 0.4 inches, and said linear shaped charge with said V shaped cross section being a PBXN-5 charge with a tin or lead sheathing and including a coreload on the order of 10 to 15 grains per foot.
 10. The method of claim 7, further comprised of said polycarbonate or laminate including polycarbonate material being of a thickness on the order of 0.35 to 0.65 inches, and said linear shaped charge with said V shaped cross section being a PBXN-5 charge with a tin or lead sheathing and including a coreload on the order of 15 to 20 grains per foot.
 11. The method of claim 7, further comprised of said polycarbonate or laminate including polycarbonate material being of a thickness on the order of 0.6 to 0.9 inches, and said linear shaped charge with said V shaped cross section being a PBXN-5 charge with a tin or lead sheathing and including a coreload on the order of 30 to 40 grains per foot.
 12. A method of serving a pattern from a material, comprising the steps of: placing a linear shaped explosive charge in proximity to said material to be severed about the pattern to be severed from said material such that portions of said linear shaped explosive charge intersect; and detonating said linear shaped explosive charge.
 13. The method of claim 12, further comprised of said linear shaped explosive charge including a V shaped cross section.
 14. The method of claim 13, further comprised of intersecting portions of said linear shaped explosive charge with said V shaped cross section are overlaid such that a second intersecting portion of said linear shaped explosive charge with said V shaped cross section that runs over top of a first intersecting portion of said linear shaped explosive charge with said V shaped cross section is deformed such that said second intersecting portion of said linear shaped explosive charge with said V shaped cross section is flattened to eliminate a cutting force of said second intersecting portion of said linear shaped explosive charge to instead provide for detonation of said first intersecting portion of said linear shaped explosive charge.
 15. The method of claim 12, further comprised of a first portion of said linear shaped explosive charge that is located closest to said material to be severed, said first portion of said linear shaped explosive charge including a reduced thickness of metal sheathing at a point where a second portion of said linear shaped explosive charge overlays said first portion of said linear shaped explosive charge.
 16. The method of claim 12, further comprised of placing a solid material between a first portion of said linear shaped explosive charge that is located closest to said material to be severed and said material to be severed at a point where a second portion of said linear shaped explosive charge overlays said first portion of said linear shaped explosive charge.
 17. A method of detonation transfer between intersecting portions of linear shaped explosive charges, comprising the steps of: placing a booster charge at a point of intersection between said intersecting portions of said linear shaped explosive charges; and detonating said linear shaped explosive charges.
 18. A method of detonation transfer between intersecting portions of linear shaped explosive charges, comprising the steps of: placing an explosive transfer charge at a point of intersection between said intersecting portions of said linear shaped explosive charges; enclosing said explosive transfer charge within a manifold; and detonating said linear shaped explosive charges.
 19. The method of claim 18 comprising the step of: transferring by said explosive transfer charge detonation to said linear shaped explosive charges.
 20. The method of claim 17, further comprising the step of: transferring by said booster charge detonation to said linear shaped explosive charges.
 21. The method of claim 12, further comprised of intersecting portions of said linear shaped explosive charge are overlaid such that a second intersecting portion of said linear shaped explosive charge runs over top of a first intersecting portion of said linear shaped explosive charge such that said second intersecting portion of said linear shaped explosive charge is flattened to eliminate a cutting force of said second intersecting portion of said linear shaped explosive charge to instead provide for detonation of said first intersecting portion of said linear shaped explosive charge.
 22. The method of claim 12 further comprised of positioning a second portion of said linear shaped explosive charge over top of a first portion of said linear shaped explosive charge over a line of severance for said pattern to be severed from said material.
 23. The method of claim 12, further comprised of intersecting portions of said linear shaped explosive charge intersecting in a mitered joint.
 24. An explosive device for severing a material, comprising: a linear explosive charge, said linear explosive charge including a coreload of 10 to 40 grains per foot; and a retainer made of a rubber, said retainer surrounding said linear explosive charge such that an area of said linear explosive charge is not surrounded by said retainer so as to face a material to be severed, and said retainer surrounding said linear explosive charge so as to provide an open space to provide an offset in a range of 0.070 to 0.300 inches between said linear explosive charge and said material to be severed upon attaching said retainer to said material, said retainer containing said linear explosive charge positioned on said material along a pattern, all bends in said pattern having turn radii of greater than or equal to 2 inches.
 25. The explosive device of claim 24, further comprised of said linear explosive charge being a linear shaped charge with a V shaped cross section.
 26. The explosive device of claim 24, further comprised of said linear explosive charge being a PBXN-5 charge with a tin or lead sheathing.
 27. An explosive device for severing a pattern from a material, comprising: a first linear shaped explosive charge; and a second linear shaped explosive charge, said first linear shaped explosive charge and said second linear shaped explosive charge being positioned so that said first linear shaped explosive charge intersects with said second linear shaped explosive charge so as to sever a pattern from a material upon detonation of said explosive device.
 28. The explosive device of claim 27 further comprised of the second linear shaped explosive charge is positioned to overlay the first linear shaped explosive charge so that said second linear shaped explosive charge is flattened over said first linear shaped explosive charge.
 29. The explosive device of claim 28, further comprised of said first linear shaped explosive charge and said second linear shaped explosive charge each including a V shaped cross section.
 30. The explosive device of claim 27, further comprised of said second linear shaped explosive charge is positioned to run over the top of said first linear shaped explosive charge, with said first linear shaped explosive charge including a reduced thickness of metal sheathing at a point where said second linear shaped explosive charge overlays said first linear shaped explosive charge.
 31. The explosive device of claim 30, further comprised of said first linear shaped explosive charge and said second linear shaped explosive charge each including a V shaped cross section.
 32. An explosive device for severing a material, comprising: a plurality of linear shaped explosive charges, said plurality of linear shaped explosive charges intersecting at a point of intersection; and a booster charge, said booster charge being located at said point of intersection between said plurality of linear shaped explosive charges.
 33. An explosive device for severing a material, comprising: a plurality of linear shaped explosive charges, said plurality of linear shaped explosive charges intersecting at a point of intersection; an explosive transfer charge, said explosive transfer charge being positioned at said point of intersection of said plurality of linear shaped explosive charges; and a manifold, said manifold enclosing said explosive transfer charge and said point of intersection of said plurality of linear shaped explosive charges. 